EP0136816A2 - Dispositif pour commander un temps de retard au cours d'un mode de reproduction à vitesse modifiée - Google Patents

Dispositif pour commander un temps de retard au cours d'un mode de reproduction à vitesse modifiée Download PDF

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Publication number
EP0136816A2
EP0136816A2 EP84305862A EP84305862A EP0136816A2 EP 0136816 A2 EP0136816 A2 EP 0136816A2 EP 84305862 A EP84305862 A EP 84305862A EP 84305862 A EP84305862 A EP 84305862A EP 0136816 A2 EP0136816 A2 EP 0136816A2
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EP
European Patent Office
Prior art keywords
signal
reproduced
circuit
frequency
delay
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP84305862A
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German (de)
English (en)
Other versions
EP0136816B1 (fr
EP0136816A3 (en
Inventor
Yasuomi Namiki
Koji Arai
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Victor Company of Japan Ltd
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Victor Company of Japan Ltd
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Publication date
Priority claimed from JP58155775A external-priority patent/JPS6047576A/ja
Priority claimed from JP58155776A external-priority patent/JPS6047577A/ja
Application filed by Victor Company of Japan Ltd filed Critical Victor Company of Japan Ltd
Publication of EP0136816A2 publication Critical patent/EP0136816A2/fr
Publication of EP0136816A3 publication Critical patent/EP0136816A3/en
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Publication of EP0136816B1 publication Critical patent/EP0136816B1/fr
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N9/00Details of colour television systems
    • H04N9/79Processing of colour television signals in connection with recording
    • H04N9/7921Processing of colour television signals in connection with recording for more than one processing mode
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11BINFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
    • G11B27/00Editing; Indexing; Addressing; Timing or synchronising; Monitoring; Measuring tape travel
    • G11B27/005Reproducing at a different information rate from the information rate of recording
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N9/00Details of colour television systems
    • H04N9/79Processing of colour television signals in connection with recording
    • H04N9/87Regeneration of colour television signals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N9/00Details of colour television systems
    • H04N9/79Processing of colour television signals in connection with recording
    • H04N9/87Regeneration of colour television signals
    • H04N9/89Time-base error compensation
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11BINFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
    • G11B15/00Driving, starting or stopping record carriers of filamentary or web form; Driving both such record carriers and heads; Guiding such record carriers or containers therefor; Control thereof; Control of operating function
    • G11B15/02Control of operating function, e.g. switching from recording to reproducing
    • G11B15/05Control of operating function, e.g. switching from recording to reproducing by sensing features present on or derived from record carrier or container
    • G11B15/087Control of operating function, e.g. switching from recording to reproducing by sensing features present on or derived from record carrier or container by sensing recorded signals
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11BINFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
    • G11B15/00Driving, starting or stopping record carriers of filamentary or web form; Driving both such record carriers and heads; Guiding such record carriers or containers therefor; Control thereof; Control of operating function
    • G11B15/02Control of operating function, e.g. switching from recording to reproducing
    • G11B15/12Masking of heads; circuits for Selecting or switching of heads between operative and inoperative functions or between different operative functions or for selection between operative heads; Masking of beams, e.g. of light beams
    • G11B15/125Masking of heads; circuits for Selecting or switching of heads between operative and inoperative functions or between different operative functions or for selection between operative heads; Masking of beams, e.g. of light beams conditioned by the operating function of the apparatus
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11BINFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
    • G11B15/00Driving, starting or stopping record carriers of filamentary or web form; Driving both such record carriers and heads; Guiding such record carriers or containers therefor; Control thereof; Control of operating function
    • G11B15/18Driving; Starting; Stopping; Arrangements for control or regulation thereof
    • G11B15/1808Driving of both record carrier and head
    • G11B15/1875Driving of both record carrier and head adaptations for special effects or editing
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11BINFORMATION STORAGE BASED ON RELATIVE MOVEMENT BETWEEN RECORD CARRIER AND TRANSDUCER
    • G11B2220/00Record carriers by type
    • G11B2220/90Tape-like record carriers

Definitions

  • the present invention generally relates to delay time control apparatuses for controlling delay times at the time of a changed speed reproduction mode, and more particularly to a delay time control apparatus for controlling one or two delay times of one or two delay circuits which delay a reproduced signal from a rotary head.
  • a magnetic tape which is played is recorded at the time of a recording mode by rotary heads having gaps of mutually different azimuth angles, and is at least recorded with a frequency modulated video signal.
  • the magnetic tape has a track pattern in which recorded positions of horizontal synchronizing signals on two mutually adjacent tracks are not aligned in the width direction of the tracks and are shifted in the longitudinal direction of the tracks.
  • the delay time control apparatus controls the one or two delay times so that it is possible to obtain a stable reproduced signal accompanying no skew phenomenon and having no color disappearance at the time of the change speed reproduction mode in which the magnetic tape moves at a tape speed different from the tape speed at the time of the recording mode.
  • the skew phenomenon and the color disappearance will be described later on in the specification.
  • a magnetic recording and reproducing apparatus employing the azimuth recording and reproducing system, is well known.
  • a magnetic tape which is recorded in a standard mode of the VTR usually has a track pattern in which recorded positions of horizontal synchronizing signals on two mutually adjacent tracks are aligned in the width direction of the tracks (so-called H-alignment). Accordingly, in a case where a PAL system color video signal is recorded on the magnetic tape, for example, the recorded positions of the horizontal synchronizing signals on two mutually adjacent tracks are aligned in the width direction of the tracks.
  • recorded sections of one horizontal scanning period (1H), containing modulated waves obtained by modulating chrominance subcarriers having inverted phases by color difference signals (R-Y), are also recorded on the mutually adjacent tracks in alignment along the width direction of the tracks.
  • the recording and reproducing time of the VTR is becoming extended.
  • the length of the magnetic tape, the diameter of a drum, and the length of one track on which the video signal is recorded remain unchanged.
  • the track widths of rotary heads are made extremely narrow, and the tape speed is reduced to 1/2 the tape speed at the time of the standard mode, for example, so as to extend the recording time to twice the recording time which is obtainable in the standard mode.
  • a difference between starting positions of two mutually adjacent tracks becomes equal to 1/2 the difference between starting positions of two mutually adjacent tracks which are formed at the time of the standard mode.
  • the H-alignment does not exist in the track pattern which is formed during an extended time mode in which the recording time is extended.
  • the recorded sections of lH, containing the modulated waves obtained by modulating the chrominance subcarriers having the inverted phases by the color difference signals (R-Y), are recorded on the mutually adjacent tracks in non-alignment along the width direction of the tracks.
  • the reproducing rotary head in addition to tracks which are pre-recorded by a rotary head having a gap of the same azimuth angle as the gap of the reproducing rotary head, the reproducing rotary head also scans over reverse tracks which are pre-recorded by a rotary head having a gap of an azimuth angle different from the azimuth angle of the gap of the reproducing rotary head.
  • a so-called reverse or opposite tracking takes place.
  • the horizontal synchronizing signals are constantly reproduced with an interval of 1H.
  • the color difference signals (R-Y) are reproduced so that the recorded section of 1H containing the carrier having the inverted phase and the recorded section of 1H containing the carrier having the non-inverted phase are alternately reproduced.
  • the reproduced PAL system color video signal is the same as the pre-recorded PAL system color video signal, as to the periodicity of the reproduced horizontal synchronizing signals and the sequence of the reproduced carrier chrominance signals.
  • the noise bar is generated in the reproduced signal from the reproducing rotary head when a large portion of the area on the magnetic tape in contact with the reproducing rotary head belongs to the reverse track.
  • the interval of the reproduced horizontal synchronizing signals becomes equal to lH/2, for example, and the sequence of the reproduced carrier chrominance signals becomes disordered.
  • the periodicity of the reproduced horizontal synchronizing signal becomes disordered as the reproducing rotary head scans across the reverse track.
  • the reproduced frequency modulated video signal is simply subjected to a frequency demodulation and is then supplied to a monitoring display device, the reproduced picture will be distorted in the horizontal direction of the picture (so-called skew phenomenon), and the color disappears at a part of the reproduced picture (hereinafter referred to as a color disappearance).
  • skew phenomenon the color disappears at a part of the reproduced picture
  • a skew part of a reproduced luminance signal wherein a skew of lH/2 is generated, is detected in a 1H/2 skew detecting circuit.
  • An output detection signal of the lH/2 skew detecting circuit is supplied to a first switching circuit as a first switching signal.
  • the first switching circuit selectively produces one of a reproduced color video signal in which the reproduced luminance signal and a reproduced carrier chrominance signal of the PAL system, for example, is multiplexed, and a delayed reproduced color video signal which is obtained by delaying the reproduced color video signal by a delay time of 1H/2 in a lH/2-delay circuit.
  • the first switching circuit In a state where the first switching circuit is producing one of the reproduced color video signal and the delayed color video signal, the first switching circuit is switched to produce the other of the reproduced color video signal and the delayed color video signal, responsive to the first switching signal (the output detection signal of the lH/2 skew detecting circuit).
  • the first switching signal the output detection signal of the lH/2 skew detecting circuit.
  • a color burst signal is extracted from the above reproduced color video signal, and the phase of the extracted color burst signal is detected in a phase detecting circuit.
  • a phase detecting circuit In a case where the sequence of the reproduced carrier chrominance signals is correct, a square wave which is inverted for every 1H is obtained from the phase detecting circuit.
  • the periodicity of the output signal of the phase detecting circuit is disordered.
  • a chrominance sequence discriminating circuit receives the output signal of the phase detecting circuit, and discriminates a disorder in the chrominance sequence from a disorder in the periodicity of the output signal of the phase detecting circuit.
  • An output signal of the chrominance sequence discriminating circuit is supplied to a second switching circuit as a second switching signal.
  • the second switching circuit is designed to selectively produce one of the reproduced carrier chrominance signal and a delayed reproduced carrier chrominance signal which is obtained by delaying the reproduced carrier chrominance signal by a delay time of 1H.
  • the second switching circuit is switched to produce the other of the reproduced carrier chrominance signal and the delayed reproduced carrier chrominance signal, responsive to the second switching signal (the output signal of the chrominance sequence discriminating circuit).
  • the output signal of the second switching circuit is multiplexed with the reproduced luminance signal, and is supplied to the first switching circuit and to the lH/2-delay circuit. As a result, a reproduced carrier chrominance signal having the correct chrominance sequence, is obtained from the second switching circuit.
  • the delay time of the reproduced color video signal that is, whether to delay the reproduced color video signal by the delay time of 1H/2 or not to delay the reproduced color video signal
  • the delay time of the reproduced carrier chrominance signal that is, whether to delay the reproduced carrier chrominance signal by the delay time of 1H or not to delay the reproduced carrier chrominance signal
  • the delay time of the reproduced carrier chrominance signal is controlled responsive to the output signal of the chrominance sequence discriminating circuit.
  • a rotary head for extended time mode play may be arranged extremely close to a rotary head for standard mode play.
  • the two kinds of rotary heads are selectively used during the changed speed reproduction mode, and the noise bar which is generated when the reproducing rotary head scans over the reverse track, is greatly reduced.
  • a skew of 0.25H is generated in this case, and it is necessary to detect this skew of 0.25H in order to reduce the skew. But, it is difficult to stably detect the skew of 0.25H.
  • Another and more specific object of the present invention is to provide a delay time control apparatus comprising comparing means for comparing levels of reproduced frequency modulated signals from first and second rotary heads which have gaps of mutually different azimuth angles and simultaneously scan over a magnetic tape during a changed speed reproduction mode, head selecting means for selectively producing one of the reproduced signals from the first and second rotary heads having the larger level responsive to an output signal of the comparing means, demodulating means for demodulating the reproduced signal which is selectively produced from the head selecting means, a variable delay circuit for delaying a reproduced video signal from the demodulating means, and a control signal generating circuit for producing a control signal responsive to the output signal of the head selecting means, and for variably controlling a delay time of the variable delay circuit by the control signal so as to produce a reproduced video signal containing a reproduced synchronizing signal which has a constant period.
  • the circuit in the apparatus may be made in the form of an integrated circuit, and the operation of the apparatus may be performed by use of a microprocessor.
  • the construction of the apparatus is simplified by the use of the integrated circuit and the microprocessor, and it is possible to reduce the size and weight of the apparatus.
  • the skew of 1.25H which is generated during the changed speed reproduction mode is detected by use of the conventional analog signal processing, it is impossible to perform a stable detecting operation.
  • the levels of the reproduced frequency modulated signals from two rotary heads are compared according to the apparatus of the present invention, it is possible to accurately detect the positions of the rotary heads, and the skew can be detected more stably compared to the conventional apparatus.
  • Still another object of the present invention is to provide a delay time control apparatus in which the above control signal generating circuit generates another control signal during a changed speed reproduction mode.
  • the magnetic tape which is played is recorded with a frequency modulated luminance signal which is obtained by frequency-modulated a luminance signal in a PAL or SECAM system color video signal, and a frequency converted carrier chrominance signal which is obtained by frequency-converting a carrier chrominance signal of the PAL or SECAM system color video signal into a low frequency range.
  • the other control signal controls another variable delay circuit which is different from the above variable delay circuit, so that the other variable delay circuit selectively delays a reproduced carrier chrominance signal or a reproduced frequency converted carrier chrominance signal by a delay time of one horizontal scanning period and produces a reproduced carrier chrominance signal having the correct chrominance sequence.
  • the reproduced carrier chrominance signal has the correct chrominance sequence, and it is possible to obtain a reproduced color picture of a high quality containing no color disappearance.
  • a further object of the present invention is to provide a delay time control apparatus which employs two rotary heads which have gaps of mutually different azimuth angles and simultaneously scan over the magnetic tape, wherein the rotary heads have a double-gap construction and a distance between the double gaps corresponds to one horizontal scanning period.
  • the apparatus of the present invention a difference between periodicities of the switching of the delay times at the time of a high-speed forward reproduction mode and at the time of a high-speed reverse (backward) reproduction mode, is small. For this reason, it is possible to simplify the construction of the apparatus.
  • Another object of the present invention is to provide a delay time control apparatus which employs two rotary heads which have gaps of mutually different azimuth angles and simultaneously scan over the magnetic tape, wherein one of the two rotary heads is a rotary head for extended time mode having a small track width, and the other of the two rotary heads is a rotary head for standard mode having a large track width.
  • the apparatus of the present invention it is possible to obtain a signal for controlling the delay time during the changed speed reproduction mode, without providing a rotary head exclusively for use in controlling the delay time.
  • By selectively using the two rotary heads it is possible to repeatedly reproduce the same field, and thus, it is possible to obtain a completely still reproduced picture.
  • Still another object of the present invention is to provide a delay time control apparatus which comprises first comparing means for comparing levels of reproduced frequency modulated signals from two rotary heads which are provided close to each other and have gaps of mutually different azimuth angles.
  • An output signal of the first comparing means is passed through an integrating circuit, so as to generate a signal in synchronism with a frequency component which is related to a number of times recorded tracks on the magnetic tape are scanned across by the rotary heads, and this signal is used to generate delay control signals which control the delay time.
  • pulses which mix into the output signal of the first comparing means due to unstable contact between the magnetic tape and the rotary heads or the like are discriminated as noise and are ignored. For this reason, it is possible to stably generate the delay control signals, and the delay time can be controlled accurately.
  • a further object of the present invention is to provide a delay time control apparatus in which a signal which is used as a reference for generating a signal for controlling the delay time, is generated in a phase locked loop.
  • a center frequency of a variable frequency oscillator within the phase locked loop is set by a voltage which is produced responsive to detection pulses which are obtained by detecting a rotation of a capstan.
  • Another object of the present invention is to provide a delay time control apparatus which comprises second comparing means for comparing levels of a reference voltage and a signal in synchronism with a frequency component which is related to a number of times recorded tracks on the magnetic tape are scanned across by two rotary heads which simultaneously scan over the magnetic tape.
  • An output signal of the second comparing means is used as a switching signal for selectively producing one of the reproduced signals from the two rotary heads.
  • the output signal of the second comparing means is also used as a reference signal for a circuit which generates delay control signals for controlling the delay time.
  • the reference voltage may be selected so that the reproduced signal from one of the two rotary heads having the larger track width is selectively obtained for a longer period of time.
  • FIG.lA shows an example of a track pattern on a magnetic tape 10 when a PAL system color video signal is recorded in a standard mode of a video tape recorder (VTR) which employs an azimuth recording and reproducing system.
  • tracks t a , t b , t c , t d , and t are formed obliquely to the longitudinal direction of the tape 10.
  • two mutually adjacent tracks are respectively formed by two rotary heads having gaps of nutually different azimuth angles.
  • One field of the PAL system color video signal is recorded in each of the tracks t through t e , however, only the beginning portions of the tracks t a through t e are shown in FIG.lA.
  • the numbers illustrated in the tracks t through t e each indicate the horizontal scanning line number and the recorded section in which the video signal of 1H (H indicates the horizontal scanning period) of this horizontal scanning line number is recorded.
  • a PAL system carrier chrominance signal is a modulated wave which is obtained by subjecting chrominance subcarriers having predetermined frequencies to a carrier suppression quadrature amplitude modulation by two kinds of color difference signals (R-Y) and (B-Y).
  • the phase of only the chrominance subcarrier which is modulated by the color difference signal (R-Y) between the two kinds of color difference signals, is inverted for every 1H.
  • the carrier chrominance signal is frequency-converted into a low frequency range and is recorded on the tracks on the tape 10.
  • the luminance signal is frequency-modulated and is recorded on the tracks on the tape 10.
  • First and second frames of the recorded video signal are respectively indicated by Fl and F2.
  • the first frame Fl of the recorded video signal is recorded on the tracks t a and t b
  • the second frame F2 of the recorded video signal is recorded on the tracks t c and t d .
  • the tracks on the tape 10 are successively formed from the left to right in FIG.lA.
  • the starting positions of two mutually adjacent tracks differ by 1.5H.
  • the recorded positions of the horizontal synchronizing signals are aligned in the width direction of the tracks between the mutually adjacent tracks.
  • the first chrominance subcarriers which have inverted phases with respect to the phases of the second chrominance subcarriers and are modulated by the color difference signals (R-Y), are recorded in alignment along the width direction of the tracks.
  • the recording and reproducing time of the VTR is becoming extended.
  • the length of the magnetic tape, the diameter of a drum, and the length of one track on which the video signal is recorded remain unchanged.
  • the track widths of rotary heads are made extremely narrow, and the tape speed is reduced to 1/2 the tape speed at the time of the standard mode, for example, so as to extend the recording time to twice the recording time which is obtainable in the standard mode.
  • a difference between the starting positions of two mutually adjacent tracks becomes equal to 0.75H which is 1/2 the difference between the starting positions of two mutually adjacent tracks which are formed at the time of the standard mode.
  • the H-alignment does not exist in a track pattern shown in FIG.2A which is formed during an extended time mode in which the recording time is extended. Accordingly, in the track pattern which is formed during the extended time mode, the recorded sections of 1H, containing the modulated waves obtained by modulating the chrominance subcarriers having the inverted phases by the color difference signals (R-Y) , are recorded on the mutually adjacent tracks in non-alignment along the width direction of the tracks.
  • the reproducing rotary head in addition to tracks which are pre-recorded by a rotary head having a gap of the same azimuth angle as the gap of the reproducing rotary head, the reproducing rotary head also scans over reverse tracks which are pre-recorded by a rotary head having a gap of an azimuth angle different from the azimuth angle of the gap of the reproducing rotary head. In other words, a so-called reverse or opposite tracking takes place.
  • the tape 10 having the track pattern shown in FIG.1A in which the H-alignment exists is played in the changed speed reproduction mode
  • one reproducing rotary head scans over a scanning locus SS shown in FIG.lA, for example.
  • the reproduced signal from this one reproducing rotary head is as shown in FIG.lB.
  • FIGS.IA and lB when a large portion of an area on the tape 10 in contact with the reproducing rotary head belongs to the reverse track, there is a great decrease in the level of the reproduced signal due to the azimuth loss effect, and a noise bar is generated in the reproduced picture.
  • a period in a vicinity of the horizontal scanning line number "4" of the first frame Fl and the horizontal scanning line number "14" in the second frame F2 are such places where the noise bar is generated.
  • the horizontal synchronizing signal is constantly reproduced with an interval of 1H.
  • the color difference signals (R-Y) are reproduced so that the recorded section of 1H indicated the boxes with the hatchings and contains the chrominance subcarrier having the inverted phase and the recorded section of 1H indicated by the boxes without the hatchings and contains the chrominance subcarrier having the non-inverted phase, are alternately reproduced.
  • the reproduced PAL system color video signal is the same as the pre-recorded PAL system color video signal, as to the periodicity of the reproduced horizontal synchronizing signals and the sequence of the reproduced carrier chrominance signals.
  • one reproducing rotary head scans over a scanning locus SL shown in FIG.2A, for example.
  • a reproduced signal from the reproducing rotary head becomes as shown in FIG.2B.
  • the noise bar is generated in the reproduced signal from the reproducing rotary head when a large portion of the area on the tape 11 in contact with the reproducing rotary head belongs to the reverse track.
  • a period in a vicinity of the horizontal scanning line number "4" of the first frame Fl, the horizontal scanning line number "7" of the second frame F2, the horizontal scanning line number "14” of the second frame F2, and a horizontal scanning line number "17” of a third frame F3, are such places where the noise bar is generated.
  • the interval of the reproduced horizontal synchronizing signals becomes equal to 1H/2, for example, and the sequence of the reproduced carrier chrominance signals becomes disordered. For this reason, when carrying out the changed speed reproduction with respect to the magnetic tape 11 having the track pattern in which the H-alignment does not exist, the periodicity of the reproduced horizontal synchronizing signal becomes disordered as the reproducing rotary head scans across the reverse track.
  • the reproduced frequency modulated video signal when the reproduced frequency modulated video signal is simply subjected to a frequency demodulation and is then supplied to a monitoring display device, the reproduced picture will be distorted in the horizontal direction of the picture (so-called skew phenomenon), and the color disappears at a part of the reproduced picture (hereinafter referred to as a color disappearance). As a result, it is only possible to obtain a reproduced picture having a poor picture quality.
  • FIG.3 a correcting apparatus shown in FIG.3 was conventionally used to prevent the generation of the skew phenomenon and the color disappearance.
  • recorded signals on the tape 11 having the track pattern shown in FIG.2A are alternately reproduced by rotary heads 13 and 14.
  • the reproduced signals from the rotary heads 13 and 14 are passed through respective pre-amplifiers 15 and 16.
  • Output signals of the pre-amplifiers 15 and 16 are supplied to respective terminals 17a and 17b of a switching circuit 17.
  • Switching pulses are supplied to the switching circuit 17 through an input terminal 18.
  • Rotation detection pulses are obtained by detecting the rotational phase of a rotary body which is mounted with the rotary heads 13 and 14 at diametrical positions thereof, by a known means.
  • the rotation detection pulses have a period of one field, and are used as the switching pulses.
  • the switching circuit 17 is switched responsive to the switching pulses, so as to selectively produce through a terminal 17c thereof the output reproduced signal of one rotary head which is carrying out the reproduction.
  • the reproduced signal from the terminal 17c is supplied to a frequency demodulating circuit 19 and to a chrominance signal processing circuit 20.
  • the tape 11 is recorded with a multiplexed signal in which a frequency modulated luminance signal and a frequency converted carrier chrominance signal are multiplexed.
  • the frequency modulated luminance signal is obtained by frequency-modulating the luminance signal of the PAL system color video signal.
  • the frequency converted carrier chrominance signal is obtained by frequency-converting the carrier chrominance signal of the PAL system color video signal into an unoccupied frequency band which is lower than the frequency band of the frequency modulated luminance signal.
  • a reproduced luminance signal is obtained from the frequency demodulating circuit 19, and is supplied to a luminance signal processing circuit 21 wherein a predetermined signal processing such as a dropout compensation and a de-emphasis is performed.
  • the chrominance signal processing circuit 20 frequency-selects the frequency converted carrier chrominance signal within the reproduced signal, frequency-converts the reproduced frequency converted carrier chrominance signal back into the original frequency band, and performs a compensating process or the like as a countermeasure against crosstalk from an adjacent track.
  • a reproduced carrier chrominance signal obtained from the chrominance signal processing circuit 20, is supplied to a 1H delay circuit 22 and to a terminal 23b of a switching circuit 23.
  • An output delayed reproduced carrier chrominance signal of the 1H delay circuit 22, is supplied to a terminal 23a of the switching circuit 23.
  • the switching circuit 23 selectively produces through a terminal 23c thereof the delayed reproduced carrier chrominance signal from the 1H delay circuit 22 or the undelayed reproduced carrier chrominance signal from the chrominance signal processing circuit 20, responsive to a signal from a chrominance sequence discriminating circuit 30 which will be described later on in the specification.
  • the output signal of the switching circuit 23 is supplied to a mixing circuit 24 and is mixed with the reproduced luminance signal.
  • the mixing circuit 24 produces a reproduced color video signal, and supplies this reproduced color video signal to a terminal 26a of a switching circuit 26, through a 1H/2 delay circuit 25.
  • the reproduced color video signal is also supplied directly, that is, without being delayed, to a terminal 26b of the switching circuit 26.
  • the output reproduced luminance signal of the luminance signal processing circuit 21 is supplied to a lH/2 skew detecting circuit 27.
  • the lH/2 skew detecting circuit 27 detects the parts shown in FIG.2B where the skew of lH/2 are generated, by detecting parts in the reproduced luminance signal where the period of the reproduced horizontal synchronizing signal is incorrect.
  • the output reproduced color video signal of the switching circuit 25 is also supplied to a color burst extracting circuit 28 wherein a color burst signal is extracted from the reproduced color video signal.
  • An output color burst signal of the color burst extracting circuit 28 is supplied to a phase detecting circuit 29 wherein the phase of the color burst signal is detected.
  • a square wave which is inverted for every lH is obtained from the phase detecting circuit 29.
  • the periodicity of the output signal of the phase detecting circuit 29 becomes disordered.
  • the chrominance sequence discriminating circuit 30 discriminates the disorder in the chrominance sequence, by detecting the disorder in the periodicity of the output signal of the phase detecting circuit 29.
  • the switching circuit 23 which is connected to one of the terminals 23a and 23b is switched and connected to the other of the terminals 23a and 23b responsive to the output signal of the chrominance sequence discriminating circuit 30. Accordingly, the reproduced color video signal in which the chrominance sequence is correct, is constantly produced through the terminal 23c of the switching circuit 23.
  • the reproduced color video signal in which the chrominance sequence is correct and the periodicity of the reproduced horizontal synchronizing signal is maintained is obtained through the output terminal 31 during the changed speed reproduction mode.
  • a rotary head for extended time mode play may be arranged extremely close to a rotary head for standard mode play.
  • the two kinds of rotary heads are selectively used during the changed speed reproduction mode, and the noise bar which is generated when the reproducing rotary head scans over the reverse track, is greatly reduced.
  • a skew of 0.25H is generated in this case, and it is necessary to detect this skew of 0.25H in order to reduce the skew. But, it is difficult to stably detect the skew of 0.25H.
  • FIG.4 shows an embodiment of an arrangement of heads in the apparatus according to the present invention.
  • Rotary heads H S1 and H S2 for standard mode play having first head gaps are fixedly mounted on a rotary body 33 such as a rotary drum with an angular separation of 180°.
  • the rotary heads H S1 and H S2 have first head gaps of mutually different azimuth angles.
  • the rotary body 33 is also mounted with rotary heads HL1 and H L2 for extended time mode play having second head gaps.
  • the rotary head H L1 is located at a position leading the rotary head H S2 by a predetermined distance in the rotating direction of the rotary body 33.
  • the rotary head H L2 is located at a position leading the rotary head H S1 by a predetermined distance in the rotating direction of the rotary body 33.
  • the rotary body 33 is constantly rotated in the direction of an arrow Xl at a rotational speed of 1500 rpm, for example.
  • a magnetic tape 35 is wrapped around the outer peripheral surface of the rotary body 33 over an angular range which is slightly larger than 180°, under the guidance of guide poles 34a and 34b.
  • the tape 35 is driven in the direction of an arrow X2 only during a forward reproduction mode, in a state where the tape 35 is pinched between a capstan (not shown) and a pinch roller (not shown).
  • the tape 35 is moved at a speed such that the tape 35 moves by one track pitch during a recording mode and during the normal reproduction mode, as the rotary body 33 undergoes a one-half revolution.
  • FIG.5 shows an embodiment of mounting height positions of rotary heads.
  • the rotary heads H S1 and H S2 each have a track width of 46 ⁇ m
  • the rotary heads H L1 and H L2 each have a track width of 32 ⁇ m.
  • the rotary heads H S1 and H Ll have gaps of the same first azimuth angle
  • the rotary heads H S2 and H L2 have gaps of the same second azimuth angle.
  • the first and second azimuth angles are selected such that one azimuth angle is inclined in a positive direction with respect to the track width direction of the rotary heads, and the other azimuth angle is inclined in the negative direction.
  • the rotary head H Ll is separated from the rotary head H S2 by a distance corresponding to a recording length of one horizontal scanning period (lH) on the tape 35, for example, along the rotating direction of the rotary heads.
  • the rotary head H L1 leads the rotary head H S2 by a distance of 310 ⁇ m in the rotating direction of the rotary body 33.
  • the rotary head H L2 leads the rotary head H S1 by a distance of 310 ⁇ m in the rotating direction of the rotary body 33.
  • the distance between the head gaps of the rotary heads H L1 and H S2 and the distance between the head gaps of the rotary heads H L2 and H S1 are respectively set to 310 ⁇ m which is an extremely small value.
  • a double-gap head shown in FIG.6 is normally used for the rotary heads H Ll and H S2 and the rotary heads H L2 and H S1 .
  • the rotary head H L1 (or H L2 ) for extended time mode play comprises a head winding 37 which is wound around a core 36, and has a gap G 1 .
  • the rotary head H S2 (or H S1 ) for standard mode play comprises a head winding 39 which is wound around a core 38, and has a gap G 2 .
  • a distance L between the two gaps is selected to a recording length in the order of several H. For example, the distance L is selected to a distance of 310 ⁇ m which is the recording length of 1H shown in FIG.5.
  • the rotary heads H S1 and H S2 having the track width of 46 ⁇ m are used.
  • the rotary heads H L1 and H L2 having the track width of 32 ⁇ m are used.
  • the rotary heads H L2 and H S2 having the same azimuth angle are used.
  • a single track is alternately scanned by the rotary heads H L2 and H S2 (or H L1 and H S1 ), and a completely still reproduced picture is obtained.
  • two rotary heads having different azimuth angles are in contact with the tape.
  • One of these two rotary heads is selected and used during the high-speed reproduction, so that the selected rotary head produces a reproduced frequency modulated signal having a larger level.
  • the present embodiment is applied to a helical scan type magnetic recording and reproducing apparatus or a helical scan type magnetic reproducing apparatus having the rotary heads H S1 , H S2 , H L1 and H L2 described heretofore.
  • description will be given with respect to a signal system of the delay time control apparatus according to the present invention.
  • FIG.7 is a systematic block diagram showing an embodiment of the delay time control apparatus according to the present invention.
  • those parts which are the same as those corresponding parts in FIGS.4 through 6 are designated by the same reference numerals, and their description will be omitted.
  • the rotary heads HLl, HL2, H S1 , and H S2 reproduce the recorded PA L system color video signal from the tape 35 having the track pattern shown in FIG.2A in which the H-alignment does not exist.
  • the PAL system color video signal is separated into a luminance signal and a carrier chrominance signal. The separated luminance signal is frequency-modulated.
  • the separated carrier chrominance signal is frequency-converted into an unoccupied frequency band lower than the frequency band of the frequency modulated luminance signal.
  • the chrominance subcarrier of the carrier chrominance signal is alternately subjected to a phase shift process and is not subjected to a phase shift process, for every one track scanning period (period of one field in this case).
  • the phase shift process shifts the phase of the chrominance subcarrier by 90° in a predetermined direction for every 1H.
  • the rotary heads H S1 and H L2 (or H S2 and H L1 ) constituting the double-gap head respectively scan over scanning loci having respective widths T S and T L shown in FIG.8.
  • the rotary heads H S1 and H L2 reproduce recorded signals from tracks which are formed by heads having the same azimuth angle as the rotary heads H S1 and H L2 .
  • the rotary head H S1 reproduces recorded signals from parts of the tracks t 4' t 6 , and t 8 indicated by hatchings in FIG.8, and the frequency modulated luminance signal within the reproduced signal from the rotary head H S1 undergoes a level change as shown in FIG.9(A).
  • the rotary head H L2 reproduces recorded signals from parts of the tracks t 5 , t 7 , and t 9 indicated by shades in FIG.8, and the frequency modulated luminance signal within the reproduced signal from the rotary head H L2 undergoes a level change as shown in FIG.9(B).
  • the output reproduced signals of the rotary heads H L2 and H Ll are passed through respective rotary transformers (not shown) and respective pre-amplifiers 41 and 42, and are supplied to respective terminals 45a and 45b of a switching circuit 45.
  • the output reproduced signals of the rotary heads H S1 and H S2 are passed through respective rotary transformers (not shown) and respective pre-amplifiers 43 and 44, and are supplied to respective terminals 46a and 46b of a switching circuit 46.
  • the switching circuit 45 is switched between the terminals 45a and 45b and the switching circuit 46 is switched between the terminals 46a and 46b, for every one track scanning period (period of one field in this case), responsive to rotation detection pulses which are applied to the switching circuits 45 and 46 through a terminal 47.
  • the rotation detection pulses are obtained by detecting the rotational phase of the rotary heads H S1 , H S2' H L1 , and H L2 .
  • the switching circuits 45 and 46 are controlled so that the switching circuit 46 is connected to the terminal 46a when the switching circuit 45 is connected to the terminal 45a. Accordingly, the output reproduced signal of the double-gap head which is scanning over the tape 35, is produced through common output terminals of the switching circuits 45 and 46.
  • the output reproduced signals of the rotary heads H L2 and H Ll for extended time mode play are supplied to a terminal 48a of a switching circuit 48.
  • the output reproduced signals of the rotary heads H L2 and H L1 are also supplied to an envelope detector 50 through an amplifier 49.
  • the output reproduced signals of the rotary heads H S1 and H S2 for standard mode play are supplied to a terminal 48b of the switching circuit.
  • the output reproduced signals of the rotary heads H S1 and H S2 are also supplied to an envelope detector 52 through an amplifier 51.
  • the switching circuit 48 is controlled responsive to a head selection signal shown in FIG.9(C) which is obtained from a waveform generating logic circuit 69 which will be described later on in the specification.
  • the switching circuit 48 is designed to selectively produce one of the reproduced signals supplied to the terminals 48a and 48b, which has the larger level.
  • the switching circuit 48 is connected to the terminal 48a so as to selectively produce the output reproduced signal of the rotary head H L2 or H Ll for extended time mode play.
  • the switching circuit 48 is connected to the terminal 48b so as to selectively produce the output reproduced signal of the rotary head H S1 or H S2 for standard mode play.
  • the reproduced frequency modulated luminance signal within the reproduced signal which is produced from the switching circuit 48 constantly has a large level as shown in FIG.9(D).
  • the level of the reproduced frequency modulated luminance signal greatly decreases during the changed speed reproduction mode when the rotary head scans over the reverse track, and the noise bar is generated at the parts where the reverse track is scanned.
  • the level of the reproduced frequency modulated luminance signal hardly decreases as shown in FIG.9(D), and it is therefore possible to obtain a reproduced picture having no noise bar during the changed speed reproduction mode.
  • the reproduced signal from the switching circuit 48 is supplied to a frequency demodulating circuit 53 wherein the reproduced frequency modulated luminance signal is frequency-demodulated.
  • the reproduced signal from the switching circuit 48 is also supplied to a chrominance signal processing circuit 54 wherein the reproduced frequency converted carrier chrominance signal is frequency-converted back into the original frequency band and is subjected to a phase shift process complementary to the phase shift process described before so as to cancel the phase shift.
  • This complementary phase shift process is also known from the British Patent No.2040135 described before.
  • a crosstalk component from the adjacent track is eliminated from the reproduced carrier chrominance signal by a comb filter within the chrominance signal processing circuit 54, and the output reproduced carrier chrominance signal of the chrominance signal processing circuit 54 is supplied to a 1H delay circuit 56 and to a terminal 57b of a switching circuit 57.
  • An output signal of the 1H delay circuit 56 is supplied to a terminal 57a of the switching circuit 57.
  • the 1H delay circuit 56 and the switching circuit 57 constitute a first variable delay circuit.
  • the output reproduced luminance signal of the frequency demodulating circuit 53 is supplied to a luminance signal processing circuit 55 wherein the reproduced luminance signal is subjected to a predetermined signal processing such as a dropout compensation and a de-emphasis.
  • the H-alignment does not exist in the track pattern which is formed on the tape 35.
  • the envelope detectors 50 and 52 are designed to detect the positive envelope of the reproduced frequency modulated luminance signal within the respective reproduced signals from the amplifiers 49 and 51.
  • the envelope detectors 50 and 52 produce signals having levels in accordance with the detected positive envelopes.
  • the output signal of the envelope detector 50 is supplied to a comparator 60 through a capacitor 58, and the output signal of the envelope detector 52 is supplied to the comparator 60 through a capacitor 59.
  • the capacitors 58 and 59 are provided so that a level deviation component in the reproduced signal which is obtained as the rotary head scans over the reverse track, is emphasized compared to a level deviation component which occurs at a low frequency due to inconsistencies in the reproducing sensitivities of the rotary heads or the like.
  • the envelope detector 50 supplies a detection signal indicated by a phantom line LP 1 in FIG.10(D) to the comparator 60 and the envelope detector 52 supplies a detection signal indicated by a solid line SP1in FIG.10(D) to the comparator 60 when the capacitors 58 and 59 are not provided.
  • the comparator 60 is designed to produce a high-level signal when the level of the detection signal LP 1 is larger than the level of the detection signal SP1, and in this case, the comparator 60 produces a signal shown in FIG.10(E).
  • the output signal of the comparator 60 has a part 79 where the pulse width is extremely narrow.
  • the selection of the rotary heads cannot be made in a stable manner by use of the signal shown in FIG.10(E) which has the extremely narrow part 79.
  • the capacitors 58 and 59 are provided for the reasons described before so as to obtain a highpass filter effect.
  • the high-frequency components of the detection signals are relatively emphasized compared to the low-frequency components.
  • the output signal of the comparator 60 becomes as shown in FIG.ll(B) when the capacitors 58 and 59 are provided.
  • the extremely narrow part 79 in the signal shown in FIG.10(E) is widened to a part 80 in the signal shown in FIG.11(B), and for this reason, it is possible to select the rotary heads in a stable manner.
  • the output signal of the comparator 60 shown in FIG.ll(B) is supplied to the switching circuit 48 as a head selection signal.
  • the output signal of the comparator 60 may also be used to produce control signals for obtaining the required delay times.
  • the contact state between the tape 35 and the rotary heads is not constantly satisfactory. The contact state becomes unstable especially at places where the rotary head begins to make sliding contact with the tape 35 and where the rotary head begins to separate from the tape 35, and the level of the reproduced signal becomes unstable at such places. Thus, an erroneous head selection may be made because of this unstable level of the reproduced signal.
  • the apparatus has a circuit part for preventing such erroneous head selection, and description will now be given with respect to the construction and operation of this circuit part by referring to FIGS.12(A) through 12(F).
  • FIG.12(A) shows the rotation detection pulses which are applied to the terminal 47, and these rotation detection pulses have the same signal waveform as the rotation detection pulses shown in FIG.10(C).
  • the output signal b of the comparator 60 becomes as shown in FIG.12(B).
  • the contact state between the tape 35 and the rotary heads becomes unstable at places where the rotary head begins to make sliding contact with the tape 35 and where the rotary head begins to separate from the tape 35.
  • the output signal b of the comparator 60 includes pulse parts 82, 83, and 84 in vicinities of the rising and falling edges of the rotation detection pulses, where the pulse width is narrower than a predetermined value.
  • the output signal b of the comparator 60 including the pulse parts 82, 83, and 84, is delayed in an integrating circuit 61.
  • the integrating circuit 61 produces a signal c shown in FIG.12(C) wherein the extremely narrow pulse parts 82 and 84 are compensated.
  • the output signal c of the integrating circuit 61 is supplied to a Schmitt trigger circuit 62 wherein the signal is converted into a square wave signal d shown in FIG.12(D).
  • the square wave signal d includes a pulse part 85 corresponding to the relatively wide pulse part 83 in the signal b.
  • the output square wave signal d of the Schmitt trigger circuit 62 is supplied to a phase comparator 64 within a phase locked loop (PLL) 63.
  • the PLL 63 variably controls the output oscillation frequency of a voltage controlled oscillator (VCO) 65 by an output phase error voltage of the phase comparator 64, and is designed to compare the phase of the output signal of the VCO 65 and the phase of the square wave signal d in the phase comparator 64.
  • the center frequency of the VCO 65 is set in accordance with the reproducing speed, responsive to an output voltage of a center frequency setting voltage generating circuit 66 which will be described later on in the specification.
  • the output oscillation frequency of the VCO 65 is controlled responsive to the output phase error voltage of the phase comparator 64, so that the phase of the output signal of the VCO 65 and the phase of the square wave signal d which includes the pulse part 85 are respectively maintained constant.
  • the time constant of the PLL 63 is set to a sufficiently low frequency, and the output oscillation frequency of the VCO 65 is prohibited from undergoing a quick change. Hence, the PLL 63 will not follow the pulse part 85 in the square wave signal d shown in FIG.12(D).
  • the center frequency f of the VCO 65 is set in relation to the number of tracks which are scanned by the rotary head by use of the following equation (1), where N is a positive integer at the time of a high-speed forward reproduction mode and is a negative integer at the time of a high-speed reverse reproduction mode.
  • FIG.13 shows a first embodiment of the center frequency setting voltage generating circuit 66.
  • a center frequency setting voltage generating circuit 66a is designed to work with the reproducing speeds of twice, five times, and nine times, and selectively produces a center frequency setting voltage depending on whether the tape moving direction for the set reproducing speed is the same as (forward) or in reverse to the tape moving direction at the time of the recording.
  • variable resistors 90, 91, and 92 are provided to generate voltages 3v, 6v, and lOv, and the three voltages are supplied to respective terminals 93a, 93b, and 93c of a switching circuit 93.
  • a voltage v is equal to the center frequency setting voltage for setting the center frequency of the VCO 65 to 35 Hz.
  • the switching circuit 93 is connected to the terminal 93a at the time of a two-times speed reproduction mode, the terminal 93b at the time of a five-times speed reproduction mode, and the terminal 93c at the time of a nine-times speed reproduction mode.
  • the switching circuit 93 selectively produces one of the voltages 3v, 6v, and 10v and supplies the selectively produced voltage to a non-inverting input terminal of a differential amplifier 98.
  • a variable resistor 95 divides a voltage Vcc from the same power source to which the variable resistors 90 through 92 are connected, so as to obtain a voltage 2v.
  • This voltage 2v is supplied to a terminal FF of a switching circuit 96.
  • the switching circuit 96 is designed to selectively produce one of the voltages supplied to terminals FF and REW thereof, responsive to a reproducing direction setting signal from an input terminal 97.
  • the switching circuit 96 selectively produces the voltage 2v supplied to the terminal FF when the reproducing direction is forward, and selectively produces the voltage Ov supplied to the terminal REW when the reproducing direction is reverse.
  • the differential amplifier 98 performs a processing which differs by 50 Hz depending on the reproducing direction, as may be seen from the equation (1).
  • the present embodiment employs a small number of voltage sources, namely, one.
  • capstan rotation detection pulses having a repetition frequency responsive to the rotational speed of the capstan, are applied to an input terminal 100 of a center frequency setting voltage generating circuit 66b.
  • the capstan rotation detection pulses are supplied to a monostable multivibrator 102 within a frequency-to-voltage (F-V) converter 101.
  • F-V frequency-to-voltage
  • this embodiment is not applied to an apparatus in which the capstan is disengaged from the pinch roller and the tape is moved solely by the rotational force of a reel during the high-speed reproduction mode, but is applied to an apparatus in which the engagement of the capstan and the pinch roller is maintained and the tape is moved at a high speed by rotating the capstan at a rotational speed which is faster than the rotational speed of the capstan at the time of the recording during the high-speed reproduction mode.
  • the monostable multivibrator 102 and an integrating circuit 103 constitute the F-V converter 101.
  • the monostable multivibrator 102 produces a pulse signal shown in FIG.15(B) having pulses with a constant pulse width.
  • the output signal of the monostable multivibrator 102 is supplied to the integrating circuit 103. Accordingly, a voltage shown in FIG.15(C) which is proportional to the repetition frequency of the capstan rotation detection pulses shown in FIG.15(A), is produced from the integrating circuit 103 and is supplied to a non-inverting input terminal of a differential amplifier 104.
  • D.C. voltages v and -v which are respectively obtained from variable resistors 105 and 106, are applied to respective terminals FF and REW of a switching circuit 107.
  • the switching circuit 107 is designed to switch and connect to the terminal FF at the time of the high-speed forward reproduction mode and connect to the terminal REW at the time of the high-speed reverse reproduction mode, responsive to a reproducing direction setting signal obtained through an input terminal 108.
  • An output voltage of the switching circuit 107 is supplied to an inverting input terminal of the differential amplifier 104.
  • the output voltage of the switching circuit 107 is used to change the center frequency by 50 Hz depending on the reproducing direction even when the reproducing speed is the same, as in the case described before.
  • the reproduced signal from the rotary head H L1 or H L2 for extended time mode play is selectively produced during a high-level period of the signal f.
  • the reproduced signal from the rotary head H S1 or H S2 for standard mode play is selectively produced during a low-level period of the signal f.
  • the predetermined reference voltage from the variable resistor 68 is selected to a value so that the low-level period of the signal f is longer than the high-level period of the signal f.
  • the period in which the reproduced signal is obtained from the rotary head H S1 or H S2 becomes longer than the period in which the reproduced signal is obtained from the rotary head H Ll or H L2 . Therefore, it is possible to prevent the picture quality from becoming deteriorated at parts where the switching of the rotary heads takes place.
  • the waveform generating logic circuit 69 generates the head selection signal.
  • This waveform generating logic circuit 69 receives the output signal f of the comparator 67, mode signals from an input terminal 70 indicative of an operation mode of the apparatus, and the rotation detection pulses from the terminal 47.
  • the waveform generating logic circuit 69 generates a head selection signal for selecting the rotary heads H S1 and H S2 during the standard mode, and generates a head selection signal for selecting the rotary heads H L1 and H L2 during the extended time mode. Further, during the high-speed reproduction mode, the waveform generating logic circuit 69 passes the signal f unchanged, as the head selection signal.
  • the waveform generating logic circuit 69 also generates a reference signal for cancelling the phase shift performed with respect to the frequency converted carrier chrominance signal in the chrominance signal processing circuit 54, and this reference signal is obtained through an output terminal 71.
  • the frequency converted carrier chrominance signal which is subjected to the phase shift and the frequency converted carrier chrominance signal which is not subjected to the phase shift are alternately reproduced with a period which is shorter than the period of the rotation detection pulses from the terminal 47, depending on the head selection which is made. For this reason, it is necessary to produce the reference signal (indicative of the rotary head from which the reproduced signal is obtained) in order to obtain the reproduced carrier chrominance signal in which the phase shift is cancelled depending on the head selection which is made.
  • FIG.16 shows a concrete circuit of an embodiment of the waveform generating logic circuit 69.
  • the output signal (the signal f at the time of the high-speed reproduction mode) of the comparator 67 is applied to an input terminal 111, and is supplied to one input terminal of a 2-input NAND circuit 112.
  • Input terminals 701 through 7° 4 correspond to the input terminal 70 shown in FIG.7.
  • a high-speed reproduction mode signal which assumed a high level only during the high-speed reproduction mode, is applied to the input terminal 70 1 .
  • a standard mode signal which assumes a high level only during the standard mode, is applied to the input terminal 7° 2 .
  • a still reproduction mode signal which assumes a high level only during the still picture reproduction mode, is applied to the input terminal 70 3 .
  • An extended time mode signal which assumes a high level only during the extended time mode, is applied to the input terminal 70 4 .
  • the high-speed reproduction mode signal is passed through a circuit which comprises a diode 113 and a resistor 114, and is supplied to the other input terminal of the NAND circuit 112.
  • the high-speed reproduction mode signal is also passed through a diode 115, and is supplied to one input terminal of a 2-input NAND circuit l16.
  • a signal waveform obtained at the input terminal 111 becomes as shown in FIG.17(A)
  • signal waveforms obtained at the input terminals 70 1 , 70 2 , 70 3 , and 70 4 respectively become as shown in FIGS.17(B), 17(C), 17(D), and 17(E).
  • periods T NS , T SES , and T STS respectively represent a normal reproduction period, a high-speed reproduction period, and a still picture reproduction period.
  • a normal reproduction period during the extended time mode is represented by T NL
  • T SEL' a high-speed reproduction period during the extended time mode
  • TSTL a still picture reproduction period during the extended time mode
  • the periods T NS , T SES , T STS , T NL' T SEL' and T STL are each shown as being a period of one frame in FIGS.17(A) through 17(O) for convenience' sake.
  • FIG.17(F) shows the rotation detection pulses at the input terminal 47 (a point F) in FIG.16.
  • FIGS.17(G), 17(H), 17(1), and 17(K) respectively show signal waveforms at points G, H, I, and K in FIG.16.
  • An output signal of the NAND circuit 116 is passed through a diode 124, and a logical product is taken between the output signal of the diode 124 and the still picture reproduction mode signal from the input terminal 70 3 .
  • the signal waveform at a connection point J between the diodes 120 and l24 becomes as shown in FIG.17(J).
  • a signal shown in FIG.17(L) at an output point L of the NAND circuit 119, and the signal shown in FIG.17(J) are supplied to the NAND circuit 122 and are converted into a signal shown in FIG.17(M).
  • the signal shown in FIG.17(M) is supplied to one input terminal M of a 2-input exclusive-OR circuit 125.
  • a high-level signal is constantly supplied to the other input terminal of the exclusive-OR circuit 125.
  • the output signal of the NAND circuit 122 is subjected to a phase inversion and is produced from the exclusive-OR circuit 125.
  • the output signal of the exclusive-OR circuit 125 produced through an output terminal 126, and is also supplied to one input terminal of a 2-input exclusive-OR circuit 127.
  • the signal waveform at an output point N of the exclusive-OR circuit 125 becomes as shown in FIG.17(N), and has an inverted phase with respect to the signal shown in FIG.17(M).
  • the output signal of the exclusive-OR circuit 125 is produced through the output terminal 126 as the head selection signal.
  • the rotation detection pulses from the input terminal 47 are supplied to the other input terminal of the exclusive-OR circuit 127, and the signal waveform at an output point O of the exclusive-OR circuit 127 becomes as shown in FIG.17(0).
  • the output signal of the exclusive-OR circuit 127 is produced through the output terminal 71.
  • the head selection signal which is obtained through the output terminal 126 of the waveform generating logic circuit 69, is supplied to the switching circuit 48 and the delay control signal generating circuit 72 shown in FIG.7.
  • the delay control signal generating circuit 72 receives the head selection signal and the mode signals from the input terminal 70, and supplies a switching pulse to the switching circuit 57 through an output terminal 73 so that the switching circuit 57 constantly produces a reproduced carrier chrominance signal having the correct chrominance sequence.
  • the delay control signal generating circuit 72 also produces delay control signals through output terminals 74 and 75 thereof, and supplies these delay control signals to a variable delay circuit 77 so as to variably control the delay time of the variable delay circuit 77.
  • the delay control signal generating circuit 72 is a count-down circuit.
  • FIG.18 shows a concrete circuit of an embodiment of the delay control signal generating circuit 72.
  • the head selection signal described before is applied to an input terminal 130.
  • the still picture reproduction mode signal is applied to the input terminal 70 3 , and a high-speed reverse reproduction mode signal which assumes a high level at the time of the high-speed reverse reproduction mode is applied to an input terminal 70 5 .
  • a high-speed forward reproduction mode signal which assumes a high level at the time of a high-speed forward reproduction mode is applied to an input terminal 70 6
  • an extended time mode signal which assumes a high level at the time of the extended time mode is applied to the input terminal 7° 4 .
  • the input terminals 70 3 through 7° 6 shown in FIG.18 correspond to the input terminal 70 shown in FIG.7.
  • the signal waveform at each part of the circuit shown in FIG.18 during the high-speed reverse reproduction mode is shown in FIGS.19(A) through 19(G) within a range T 1 .
  • the head selection signal is applied to the input terminal 130, and the head selection signal is supplied to an inverter 131 through a diode D 1 .
  • the phase of the head selection signal is inverted in the inverter 131, and the inverter 131 produces a signal shown in FIG.19(A) within the range T 1 .
  • the output signal of the inverter 131 is produced through the output terminal 74 as a control signal, and is also supplied to one input terminal of a 2-input exclusive-OR circuit 132.
  • the high-level high-speed reverse reproduction mode signal from the input terminal 705, is passed through diodes D 4 and D 5 and a resistor R 1 , and is supplied to an inverter 134.
  • the inverter 134 produces a low-level signal shown in FIG.19(B) within the range T 1 , and supplies this low-level signal to respective reset terminals of J-K flip-flops 142 and 144.
  • the high-speed reverse reproduction mode signal is also passed through the diode D 4 and is supplied to an inverter 133 as a high-level signal shown in FIG.19(C) within the range T l .
  • the inverter 133 produces a low-level signal, and supplies this low-level signal to the other input terminal of the exclusive-OR circuit 132.
  • a pulse signal shown in FIG.19(D) within the range T 1 which is in phase with the output signal of the inverter 131, is obtained from the exclusive-OR circuit 132.
  • the output pulse signal of the exclusive-OR circuit 132 is supplied to respective clock input terminals of the flip-flops 142 and 144.
  • a high-level signal (voltage) is applied to a J-input terminal and a K-input terminal of the flip-flop 142.
  • a pulse signal shown in FIG.19(E) within the range T 1 which reverses state responsive to every rising edge of the pulse signal applied to the clock input terminal of the flip-flop 142, is produced through a Q l -output terminal of the flip-flop 142.
  • the output pulse of the flip-flop 142 is produced through the output terminal 75 as a control signal, and is also supplied to a 2-input exclusive-OR circuit 143 together with the high-level high-speed reverse reproduction mode signal shown in FIG.19(C) within the range T l .
  • the exclusive-OR circuit 143 produces a pulse signal shown in FIG.19(F) within the range T 1 , which has an inverted phase with respect to the output pulse signal of the flip-flop 142 shown in FIG.19(E) within the range T 1 .
  • the output pulse signal of the exclusive-OR circuit 143 is supplied to a J-input terminal and a K-input terminal of the flip-flop 144. Consequently, a pulse signal shown in FIG.19(G) within the range T 1 is produced through a Q 2 -output terminal of the flip-flop 144.
  • the high-level extended time mode signal from the input terminal 70 4 is passed through inverters 135 and 136, and is applied to a cathode of a diode D 7 so as to turn the diode D 7 OFF.
  • a low-level output signal of the inverter 135 biases a diode D 8 in the forward direction. Accordingly, the high-level output signal of the diode D S shown in FIG.19(C) within the range T 1 , is applied to the inverter 134 through the resistor R 1 as described before, but the signal level at a connection point between a resistor R 2 and an anode of the diode D 8 is low because the diode D 8 is turned ON.
  • the output signal of an inverter 137 assumes a high level
  • an output signal of an inverter 138 assumes a low level. Consequently, a diode D 11 is turned OFF, and a diode D 12 is turned ON.
  • the diode D 12 is turned ON, the transmission of the pulse signal shown in FIG.19(A) within the range T 1 , which is obtained through the input terminal 130, an inverter 139, and a resistor R 3' is blocked.
  • the output signal of the flip-flop 144 is passed through a resistor R 4 and a diode D 9 , and the pulse signal shown in FIG.19(G) within the range T 1 is obtained from a connection point between cathodes of the diodes D 9 and D 10 .
  • the pulse signal from the connection point between the cathodes of the diodes D 9 and D 10 is passed through inverters 140 and 141, and is produced through the output terminal 73 as a control signal.
  • the control signals produced through the output terminals 74 and 75 are respectively supplied to the variable delay circuit 77 shown in FIG.7.
  • the delay time in the variable delay circuit 77 is controlled according to a combination of high and low levels (logic levels "1" and "0") of the control signals which are obtained from the output terminals 74 and 75.
  • the relationships of the levels of the control signals from the output terminals 74 and 75 and the delay time in the variable delay circuit 77, are shown in the following table 2.
  • a mixing circuit 76 mixes the reproduced luminance signal and the reproduced carrier chrominance signal, and produces a reproduced color video signal. Accordingly, the delay time of the variable delay circuit 77 which delays the output reproduced color video signal of the mixing circuit 76, becomes as shown in FIG.19(H) within the range T 1 during the high-speed reverse reproduction mode.
  • the unit of the numerical values is one horizontal scanning period, that is, H.
  • the control signal from the output terminal 73 is applied to the switching circuit 57 shown in FIG.7 as a switching signal.
  • the switching circuit 57 is connected to the terminal 57a when the switching signal assumes a low level, and is connected to the terminal 57b when the switching signal assumes a high level.
  • the output reproduced carrier chrominance signal of the chrominance signal processing circuit 54 is delayed by a delay time shown in FIG.19(I) within the range T 1 , and the chrominance sequence is maintained to the correct chrominance sequence which is in conformance with the PAL system.
  • the reproduced carrier chrominance signal having the correct chrominance sequence is supplied to the mixing circuit 76.
  • FIG.20A shows a track pattern on the tape 35 which is recorded in the extended time mode, and scanning loci of rotary heads which are selected when this tape 35 is played in the high-speed reverse reproduction mode.
  • the track pattern themselves shown in FIG.20A and FIG.21A which will be described later on in the specification, are the same as the track pattern shown in FIG.2A. It will be assumed that a track t 18 which is recorded with the first one field of a fifth frame F5, is recorded with a rotary head having a gap of the same azimuth angle as the gaps of the rotary heads H L2 and H S2 . Further, it will be assumed that the rotary heads H L2 and H S1 simultaneously scan over the tape 35.
  • centers of the rotary heads H L2 and H S1 which are selected move along the scanning loci indicated by solid lines in FIG.20A.
  • a switching takes place so that the reproduced signal is selectively obtained from the rotary head H S1 .
  • the switching takes place and the reproduced signal is selectively obtained from the rotary head H S1 from a position 150S shown in FIG.20A.
  • a switching takes place at a position 151S at a border between tracks t 17 and t 16 , so that the reproduced signal is selectively obtained from the rotary head H L2 which leads the rotary head H S1 by the distance corresponding to the recording length of 1H.
  • the rotary head H L2 begins to reproduce the recorded signals within the period of the scanning line number "11" in the latter half of the fourth frame F4.
  • a switching takes place when the rotary head H L2 reaches a position 152L shown in FIG.20A at a border between tracks t16 and t 15 , so that the rotary head H S1 reproduces recorded signals from the track t 15 from a position 152S up to a position 153S.
  • a switching takes place so that the rotary head H L2 reproduces recorded signals from a track t 14 from a position 153L up to a position 154L.
  • a switching takes place so that the rotary head H S1 begins to reproduce recorded signals from a position 154S on a track t 13 .
  • FIG.20B a reproduced signal which is schematically shown in FIG.20B, is produced from the switching circuit 48 shown in FIG.7.
  • numbers represent the horizontal scanning line numbers of the reproduced luminance signals
  • hatchings represent periods in which the chrominance subcarrier of the color difference signal (R-Y) is phase inverted
  • solid lines between the numbers represent positions where the horizontal synchronizing signals are reproduced.
  • the reproduced color video signal is delayed in the variable delay circuit 77 by a delay time as shown in FTG.19(H), and this delay time is changed in the sequence of 0 ⁇ 3/4 ⁇ 2/4 ⁇ 1/4 ; 0 ⁇ 3/4 ⁇ 2/4 ⁇ 1/4 ⁇ 0 ⁇ ...
  • the reproduced carrier chrominance signal is delayed in the variable delay circuit 77 by a delay time as shown in FIG.19(I), and this delay time is changed in the sequence of 0 ⁇ 1 ⁇ 1 ⁇ 1 ⁇ 1 ⁇ 0 ⁇ 0 ⁇ 0 ⁇ 1 ; ... (where the unit is H) every tim the switching of the rotary heads H L2 and H S1 takes place.
  • the reproduced carrier chrominance signal which is obtained from the variable delay circuit 77
  • the phase of the chrominance subcarrier of the color difference signal (R-Y) is inverted for every 1H, and the chrominance sequence is in conformance with the PAL system.
  • the horizontal synchronizing signals are constantly reproduced with a period of lH. Therefore, a reproduced color video signal having the chrominance sequence and the sequence of the scanning line number which are schematically shown in FIG.20C, is produced through an output terminal 78.
  • the reproduced signal shown in FIG.20B is produced up to the position 150L shown in FIG.20A.
  • the signals in the scanning line numbers "320" through “323" of the fourth frame F4 shown in FIG.20B are reproduced as shown in FIG.20C.
  • the reproduced color video signal becomes as shown in FIG.20C in which the noise corresponding to 0.5H is generated immediately before the signal in the scanning line number "14" of the fourth frame F4 is reproduced.
  • the delay time of the variable delay circuit 77 is equal to OH, and the delay time of the reproduced carrier chrominance signal is equal to 1H. Accordingly, the information content of the reproduced color video signal becomes as schematically shown in FIG.20C.
  • the video information of the reproduced color video signal in a period of OH to 3H/4 immediately after the switching of the rotary heads takes place is replaced by the video information immediately prior thereto, and a noise part is generated.
  • the high-speed reproduction is performed with a speed which is in the order of ten times the speed with which the tape is moved at the time of the recording, and such a noise part can essentially be neglected in the reproduced picture.
  • FIGS.20A and 21A the scanning loci of the rotary heads are shown for high-speed reproductions performed with a speed which is 100 times the speed with which the tape is moved at the time of the recording, for convenience' sake only so as to simplify the drawings, and such high-speed reproductions in the order of 100 times is not carried out in actual practice.
  • the horizontal synchronizing signals are generally reproduced with a period of 1H, and the skew is not generated. Accordingly, the chrominance sequence is correct, and it is possible to obtain a reproduced picture of a satisfactory picture quality during the high-speed reverse reproduction mode.
  • the head selection signal described before is applied to the input terminal 130 of the delay control signal generating circuit 72 shown in FIG.18.
  • the output signal waveform of the inverter 131 becomes as shown in FIG.19(A) within a range T 2 .
  • the signal level becomes high at the input terminals 70 4 and 706. Consequently, a signal shown in FIG.19(B) in the range T 2 is applied to the respective reset terminals of the flip-flops 142 and 144.
  • the inverter 133 receives a signal shown in FIG.19(C) in the range T 2 , and the exclusive-OR circuit 132 produces a signal shown in FIG.19(D) in the range T 2 .
  • a signal shown in FIG.19(E) in the range T 2 is produced through the Q 1 -output terminal of the flip-flop 142, and a signal shown in FIG.19(F) in the range T 2 is produced from the exclusive-OR circuit 143.
  • a control signal shown in FIG.19(G) in the range T 2 is produced through the output terminal 73.
  • the delay time of the variable delay circuit 77 changes as shown in FIG.19(H) within the range T 2 . Further, the delay time of the reproduced carrier chrominance signal changes dependent on the 1H delay circuit 56 and the switching circuit 57, as shown in FIG.19(I) within the range T 2 .
  • the rotary heads HL2 ( or H L1 ) and H S1 ( or H S2 ) are selected, and centers of the scanning loci of the selected rotary heads become as indicated by solid lines in FIG.21A, for example.
  • the output reproduced signal of the switching circuit 48 becomes as schematically shown in FIG.21B, and a skew of 0.25H is constantly generated at points 1701, 1702, 1703, and 170 4 where the switching of the rotary heads takes place.
  • the delay times are controlled as shown in FIGS.19(H) and 19(I) in the range T 2 .
  • the delay times are controlled with a period which corresponds to eight of such units, as may be seen from FIGS.19(H) and 19(1) in the range T 2'
  • a reproduced color video signal which is schematically shown in FIG.21C, in which the skew is not generated and the chrominance sequence is correct, is produced through the output terminal 78.
  • the output signal of the inverter 131 shown in FIG.18 assumes a low level as shown in FIG.19(A) within a range T 3 .
  • the signal level is high at the input terminal 70 4
  • the signal levels are low at the input terminals 70 3 , 70 5 , and 7° 6 .
  • the output signal of the inverter 134 assumes a high level as shown in FIG.19(B) within the range T 3 .
  • the input signal of the inverter 133, the output signal of the flip-flop 142, and the output signal of the exclusive-OR circuit 143 respectively assume a low level as shown in FIGS.19(C), 19(E), and 19(F) within the range T 3 .
  • the output signal of the exclusive-OR circuit 132 and the control signal produced through the output terminal 73 respectively assume a high level as shown in FIGS.19(D) and 19(G) within the range T 3 .
  • the delay time of the variable delay circuit 77, and the delay time of the reproduced carrier chrominance signal which is supplied to the mixing circuit 76 are respectively equal to zero as shown in FIGS.19(H) and 19(I) within the range T 3 .
  • the rotary heads will not scan over a reverse track during the normal reproduction, and for this reason, the operation of controlling the delay times is stopped.
  • the circuit part reaching the delay control signal generating circuit 72 from the comparator 60 performs a digital signal processing. Accordingly, it is relatively easy to make this circuit part in the form of an integrated circuit.
  • the logic operations may be performed by use of a microprocessor, and the circuit construction may be simplified.
  • the present invention is not limited to the case where the distance between the gaps of the two rotary heads constituting the double-gap head is equal a distance which corresponds to a period of 1H, and this distance may be equal to a distance which corresponds to a period of several H.
  • the following table 3 shows the quantity and sequence of the delay times for high-speed reproductions carried out in the extended time mode and the standard mode, with respect to a magnetic tape having a track pattern shown in FIG.2A in which the shift of 0.75H exists, for the case where the distance between the gaps of the two rotary heads corresponds to a period of 1H, and for the case where the distance between the gaps of the two rotary heads corresponds to a period of 2H.
  • the numbers under a column "Y+C” indicate the delay times of the variable delay circuit 77, and the numbers under a column “C” indicate the delay times of the reproduced carrier chrominance signal which is supplied to the mixing circuit 76. Further, in the table 3, the unit of the delay times is H.
  • the present inventors have examined the delay times for a case where the distance between the gaps of the two rotary heads corresponds to a period of 5H/4, for example.
  • an optimum distance between the gaps of the two rotary heads is equal to a distance corresponding to a period of 1H.
  • the present invention may be applied to the reproduction of a color video signal in which the phase or frequency of the chrominance subcarrier of the carrier chrominance signal changes for every 1H.
  • the present invention may be applied to the reproduction of a SECAM system color video signal.
  • the present invention may also be applied to the reproduction of a black-and- white video signal.
  • the first variable delay circuit which is constituted by the 1H delay circuit 56 and the switching circuit 57 shown in FIG.7, may be provided in an input stage of the chrominance signal processing circuit 54. It is not essential to employ a double-gap head, and moreover, one of the two rotary heads which constitute the double-gap head may be used for other purposes such as for carrying out a changed speed reproduction.
EP84305862A 1983-08-26 1984-08-28 Dispositif pour commander un temps de retard au cours d'un mode de reproduction à vitesse modifiée Expired - Lifetime EP0136816B1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
JP155776/83 1983-08-26
JP155775/83 1983-08-26
JP58155775A JPS6047576A (ja) 1983-08-26 1983-08-26 変速再生時における遅延時間制御信号発生回路
JP58155776A JPS6047577A (ja) 1983-08-26 1983-08-26 変速再生時における遅延時間制御装置

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EP0136816A2 true EP0136816A2 (fr) 1985-04-10
EP0136816A3 EP0136816A3 (en) 1986-04-09
EP0136816B1 EP0136816B1 (fr) 1990-04-18

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US (1) US4672469A (fr)
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EP0231106A2 (fr) * 1986-01-22 1987-08-05 Sony Corporation Procédé et appareil pour l'enrégistrement et la réproduction magnétique
EP0293046A1 (fr) * 1987-05-29 1988-11-30 Koninklijke Philips Electronics N.V. Dispositif pour reproduire un signal de luminance à partir d'un support d'enregistrement magnétique
EP0413644A1 (fr) * 1989-08-16 1991-02-20 STMicroelectronics S.A. Circuit de comparaison de signaux haute fréquence modulés en amplitude
GB2278486A (en) * 1993-05-26 1994-11-30 Mitsubishi Electric Corp A method of switching between rotating heads by comparing their output levels
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JPS62200890A (ja) * 1986-02-28 1987-09-04 Sony Corp 再生装置
US4796104A (en) * 1986-04-07 1989-01-03 Victor Company Of Japan, Ltd. Video signal recording and reproducing apparatus performing time-lapse recordings compatible with standard-type apparatuses
US5220736A (en) * 1987-03-19 1993-06-22 Canon Kabushiki Kaisha Reproducing apparatus with time base corrector
KR920006751Y1 (ko) * 1989-12-16 1992-09-26 삼성전자 주식회사 비디오 테이프 레코더의 lp 모드 다기능시 칼라신호 보상회로
KR930005339B1 (ko) * 1990-12-22 1993-06-17 주식회사 금성사 더블 어지뮤즈 4헤드 vtr에서 변속재생시 에러 보정회로
JP3446372B2 (ja) * 1994-11-14 2003-09-16 ソニー株式会社 ディジタルデータ記録/再生装置および方法
JP3572759B2 (ja) * 1995-11-21 2004-10-06 松下電器産業株式会社 磁気記録再生装置
DE69633470D1 (de) * 1995-12-14 2004-10-28 Victor Company Of Japan Magnetwiedergabegerät
EP0860089A2 (fr) * 1996-09-11 1998-08-26 Koninklijke Philips Electronics N.V. Systeme pour la reproduction multivitesse de signaux televisuels de couleur enregistres et pour la correction d'erreurs de sequences de couleurs dans des signaux televisuels de couleur reproduits
US7391251B1 (en) 2005-11-07 2008-06-24 Pericom Semiconductor Corp. Pre-emphasis and de-emphasis emulation and wave shaping using a programmable delay without using a clock

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EP0231106A3 (en) * 1986-01-22 1989-02-22 Sony Corporation Magnetic recording and/or reproducing apparatus and methmagnetic recording and/or reproducing apparatus and methods ods
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EP0293046A1 (fr) * 1987-05-29 1988-11-30 Koninklijke Philips Electronics N.V. Dispositif pour reproduire un signal de luminance à partir d'un support d'enregistrement magnétique
EP0413644A1 (fr) * 1989-08-16 1991-02-20 STMicroelectronics S.A. Circuit de comparaison de signaux haute fréquence modulés en amplitude
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US5625504A (en) * 1992-09-10 1997-04-29 Hitachi, Ltd. Magnetic recording and reproducing system
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Also Published As

Publication number Publication date
DE136816T1 (de) 1985-09-26
EP0136816B1 (fr) 1990-04-18
EP0136816A3 (en) 1986-04-09
DE3482018D1 (de) 1990-05-23
US4672469A (en) 1987-06-09

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